SU1681403A1 - Matrix image photoelectric transducer - Google Patents

Abstract

The invention relates to the field of image transmission and analysis and can be used in characterization systems of a single measurement source in space. The aim of the invention is to increase speed and simplification. A matrix photoelectric image converter contains a photomatrix 1 made of photosensitive cells 2, each of which consists of two photosensitive elements ( PSE), one of which is an element of the first group 3, and the other is an element of the second group 4, the system is horizontal x and vertical busbars 5 and 6, clock pulse generator 7, two power sources 8 and 9, a group of two-position keys 10, a shift register 11, the first and second groups of diodes 12 and 13. The presented connection

Description

The invention relates to the transmission and analysis of images and can be used in systems for determining the characteristics of a single radiation source in space.

The purpose of the invention is to increase speed and simplify.

FIG. 1 is a block diagram of a matrix photoelectric image converter.

A matrix photoelectric image converter contains a photomatrix 1 made of photosensitive cells 2, each of which consists of two photosensitive elements (PSEs), one of which is an element of the first group 3, and the other is an element of the second group 4, and horizontal and vertical busbars 5 and 6, clock pulse generator (GTI) 7, two sources 8 and 9 of the power supply, while the direction of switching on the first source 8 is opposite to the direction of switching on the second source 9, a group of two-position 10, shift register 11, first and second groups of diodes 12 and 13. Odd and even horizontal current busbars 5 are formed, and odd and even vertical current busbars 6 are formed. Pairs are formed so that each of them The driver includes one odd bus: i.e. the first pair includes the first odd and first even bus, the second - the second odd and second even bus, etc. The odd vertical busbars are connected in order with the corresponding odd horizontal busbars, i.e. The first odd vertical tire 6 is connected to the first odd horizontal tire 5, the second odd vertical tire 6 is connected to the second odd horizontal tire 5, and so on. The first group 3 of the PSE of the photomatrix 1 is connected between odd and even current-carrying buses of horizontal pairs, and the second group of the PSE is included between odd and even current-carrying buses of vertical pairs. Even horizontal buses 5 through the first group of diodes 12 are connected to the signal bus of the X coordinate, and even vertical current-carrying buses 6 through the second

a group of diodes 14 are connected to the signal line of the coordinate Y,

This allows instead of two channels of horizontal and vertical scanning to use one channel, i.e., instead of two groups of two-position keys, use one group of two-position keys 10, and instead of shift registers of horizontal and vertical scanning, use

one register 11 shift.

In the scanning channel, each odd toe horizontal bus 5 is connected to the information inputs of the corresponding two-position keys

10. The control inputs of the on-off keys 10 are connected to the outputs of the shift register 11 connected to the GTI 7. The second positions of the on-off keys 10 are combined and connected to the second source

9 meals.

The proposed connection of the PSE to the tires of the photomatrix 1 allows the PSE to be performed in one photosensitive layer, which ensures the same sensitivity of reading the signals in both coordinates. ,

The matrix photoelectric image converter (MPPI) works as follows.

Upon receipt of the clock pulses at the input of the shift register 11, alternately with each clock pulse, a signal appears that switches the corresponding key 10 from the second position to the first. By this, alternately to the first source 8, with each clock pulse, there is connected one odd chokesal horizontal bus 5 and one odd current-carrying vertical bus 6.

The remaining odd buses remain connected to the second power source 9. By this, the current from the first power source 8 is connected via the connected to: Noah, horizontal horizontal current lead yc bus 5, connected to it PSF, the horizontal / horizontal bus of this pair of buses, the corresponding diode 12 enters neither gyhod along the X coordinate of the MFPI, and also through the corresponding vertical the odd bus 6, connected to it, the PSE 4, even vertical bus 6 of this pair of tires, the corresponding diode

13 nocrynaei and exit on the coordinate of MPPI. The voltage from the second power source 9 through the second positions of the remaining keys 10 and the odd buses 5, 6, PSEs connected to them, and the corresponding even buses 5, 6 is supplied to the diodes 12, 13 connected to the even buses,

Thus, the outputs along the X and Y coordinates are signals from only one vertical even and one one-dimensional horizontal even bus. During the reading of one frame, i.e. a series of n clock pulses, where n is the number of horizontal odd tires, all the PSEs of matrix 1 are polled.

The magnitude of the signals depends on the illumination of the PSEs connected to the even buses that are currently being polled.

The presented PSE connection in the photomatrix allows them to be placed in one layer, which ensures the same sensitivity of reading optical signals in both coordinates, and also simplifies the design of the device, i.e. one scan channel is eliminated.

This increases the reliability of the device.

Claims (1)

Invention Formula A matrix photoelectric image converter containing a system of main horizontal and vertical tires and a matrix of photonic cells, each of which contains a first photosensitive element connected to the respective main vertical buses, a clock generator impulses, controllable keys, a shift register, a clock input of which is connected to the output of a clock operator, and outputs to a control input of a safe key, diodes and a power source, characterized in that, in order to improve speed and simplification, additional vertical and horizontal tires, and in each photosensitive cell - the second photosensitive element inserted between the corresponding main and additional horizontal tires, the first photosensitive elements are connected to the corresponding additional vertical busbars, with the outputs of the additional horizontal busbars connected to the cathodes of the respective diode, the knowledge of which is combined and the first output of the matrix photoelectric image converter; the outputs of the additional vertical chic are connected to the cathodes of the respective diodes whose anodes are combined and the second output of the matrix photoelectric image converter; the first inputs of the controlled keys are combined and connected to the negative terminal of the power source; the second inputs the control keys are combined and connected to the positive output of the power source, the output of each control key is connected to the input of the corresponding horizontal bus, each main The horizontal bus is connected to the corresponding main vertical bus.